EA008901B1 - A jar for use in a downhole toolstring - Google Patents

Abstract

A jar (10), for use in a downhole toolstring comprising: a hollow housing (11); a jar mandrel (13); a latch sub (14); one or more latch keys; (16); a cam surface (17); a chamber (23); a compression spring; and an adjuster (24). The hollow housing (11) supports, moveably retained therein, the jar mandrel (13). The jar mandrel (13) and the latch sub (14) are releasably securable together by means of the one or more latch keys (16); and each latch key (16) is moveable between a latching position, in which the latching sub (14) and the jar mandrel (13) are connected together, and a release position permitting separation thereof. An adjuster portion (51) is threadedly connected to the jar mandrel (13) such that rotation of the adjuster mandrel (47) relative to the jar mandrel (13) alters the length of the chamber (23) and hence the degree of compression of the compression spring (24).

Description

FIELD OF THE INVENTION

The present invention relates to a shock jar for use in an downhole drill.

State of the art

In the oil and gas industry, it is common practice to use drill bits during oil or gas exploration work or when preparing a wellbore for production.

These drill bits are lowered or driven into the wellbores and include a variety of devices that, when placed in the well, can be used inside the wellbores to perform predetermined tasks.

A wellbore is rarely straight and with parallel sides.

Sometimes the reason for this is the need to drill sections of the wellbore at angles to other parts of it in order to avoid the passage of difficult geological formations, and more significantly, in order to make sure that the wellbore penetrates oil and gas bearing sites as much as possible.

In addition, the pressures that are present underground in the boreholes can be very significant. Under the influence of these pressures, shale and other relatively soft geological types can invade the wellbore and thus cause it to become uneven.

Another reason for the unevenness of the wellbore is the so-called “leaching”, which is formed when fluid flows in the surrounding rock cause destruction and / or collapse of the wellbore.

All of the aforementioned causes of unevenness can cause difficulty when trying to use equipment for exploration or production inside the wellbore.

For example, there is a problem common to a drill string when it, when lowering into the wellbore on an auxiliary rope (i.e., on a relatively thick rope that supports the downhole drill string and sometimes leads wires to the information transmission unit to it) passes through a narrowed or a bent portion of the wellbore, and then gets stuck in this place when the wire rope is wound to pull the drill to the surface.

Under such conditions, there is a limit to the pulling force that surface operators can apply to the auxiliary rope.

The main reason for this is the risk of rupture of the rope, as a result of which the drill will remain stuck in the wellbore.

As an auxiliary rope, the so-called “cable rope” is usually used, having a single strand with a diameter size, usually 0.108 or 0.125, or a “braided rope”, which is multi-strand, with thinner wire strands that are twisted or bound to give durability. Typically, these ropes come in diameters of 3/16 and 7/32, and sometimes more. This type of rope is stronger and more commonly used in heavy duty operations such as fishing.

In such circumstances, it is necessary to wind the entire length of the wire rope (possibly more than many tens of thousands of feet), and then lower the stronger rope with additional equipment to clean the end of the torn rope and attach it to the drill in order to try to pull it out.

This practice does not justify itself, and not least because it takes a lot of time.

Since an oil rig’s operating time usually costs tens of thousands of dollars a day, it is imperative that rig operators rescue stuck equipment as quickly as possible.

For this reason, it has become commonplace to include the so-called “jar” in the drill.

In general terms, a mechanical spring jar is a device that is included in a drill, which, if necessary, uses limited traction exerted through the auxiliary rope in order to apply a certain mass to the spring, overcoming the force of its resistance, and then release it so that the energy resulting from the tension of the auxiliary rope pushes this mass into part of the drill.

This gives an impulse to the drill, which is often sufficient to release a stuck tool.

In the patents under the numbers I8 5052485 and I8 5267613 there is a description of two known types of jar.

A known method is when an adjustment mechanism is provided in the drill string for regulating the traction required to tension the auxiliary rope. This makes it possible to match the force required to control the jar and the strength of the auxiliary wire used and / or the weight of the drill before the drill is placed in the wellbore.

One of the known forms of jar is a cylindrical casing having a hollow inner

- 1 008901 nude part of a cylindrical shape.

In this inner part, the jar spindle and the lock sub of the permanent packer are attached to each other by means of a detachable connection, and in the working position the jar spindle is placed above the lock sub of the constant packer.

The castle sub of the permanent packer has a hoop or convexity of another kind, which supports the compression spring that defines the hollow cylinder. The castle sub of the permanent packer and / or the spindle of the jar runs along the center of the spring, the end of which, located opposite the hoop, abuts against the next bulge, which protrudes from the wall of the hollow casing. The next bulge and the hoop between them define the boundaries of the elongated chamber in which the compression spring is located.

The means for interconnecting the spindle of the jar and the lock sub of the permanent packer includes an annular group of lock keys, which can be moved in the radial direction in the inner and outer sides with respect to the spindle of the jar.

A system of springs or other elastically deformable parts forces the lock keys to move radially outward in a position in which they engage with a groove or recess formed radially in the inner surface at the upper end of the hollow cylindrical lock sub of the permanent packer. The groove is machined during the manufacturing process of the lock sub of the permanent packer to limit the ring-shaped shoulder of the profile corresponding to the lock keys.

The inner part of the casing contains one or more cam surfaces, which, when the spindle of the jar moves upward through the casing, engages lock keys.

This forces the lock keys to move inward with respect to the spindle of the jar. This, in turn, leads to their release from the clamping fingers of the castle sub of the permanent packer.

When the jasper spindle and the lock sub of the permanent packer are fastened together, any similar upward movement of the jar spindle causes a similar movement of the lock sub of the constant packer. Therefore, the initial movement occurs with overcoming the compression spring resistance acting between the hoop and the bulge protruding from the casing wall.

Thus, when the cam surface releases the lock keys from the clamping fingers, the potential energy accumulated in the auxiliary cable immediately reacts and pushes the jar spindle inside the casing further up and forces the hammer-shaped part attached to the jar spindle to hit the anvil installed inside the casing, and, thus, transmit a vertical impulse to the casing, and from it and the next part of the drill attached to it.

The part of the jar spindle, which is located in its upper part, protrudes from it through an opening in the upper end part of the casing.

This end of the spindle of the jar contains an ordinary rope lock for attaching to the auxiliary rope of such a type that when the drill is stuck in the well, this auxiliary rope is used to pull the spindle of the jar and the locking sub of the permanent packer up, overcoming the resistance of the compression spring until until the cam surface releases the lock keys from the clamping fingers.

In a typical embodiment, the drill includes several cargo rods placed directly under the cable lock. During the movement of the jar spindle and the lock sub of the permanent packer up, the auxiliary rope is pulled. When the lock keys are released, the potential energy accumulated in the auxiliary cable is converted into kinetic energy, which accelerates the mass of cargo rods.

Rapid upward movement of the load rods directs the hammer to the anvil to give an impulse to the stuck tool, as described above. By means of this drill, significant impulses can be transmitted.

The length of the lock sub of the permanent packer in relation to the spindle of the jar can be effectively adjusted, since its upper end part passes through the jumper in the lower end part of the casing, and the dimensions of the lock sub of the constant packer above the jumper and the holes through which it passes are provided to prevent the course of the castle sub of the permanent packer through the jumper down.

The opposite (during operation, lower) end part of the lock sub of the constant packer is elongated in the direction of the open lower end part of the casing and has a threaded thread. The mounting nut is screwed onto this end portion of the protruding threaded portion. Thus, using a wrench, you can move the installation nut up and down relative to the casing by turning the installation nut clockwise or counterclockwise.

Since the compression spring is located between the above-mentioned jumper and the washer located on the installation nut, so that it surrounds the locking sub of the permanent packer, adjusting the installation nut in this way changes the length of the chamber in which the spring is contained

- 2 008901 compression.

This adjustment of the length of the chamber, in turn, changes the preload applied to the compression spring. And this, in turn, affects the force required to pull the lock sub of the permanent packer and the spindle of the jar up until the lock keys engage with the cam surface. Thus, it is possible to align the operational load of the jar with the strength of the auxiliary rope used to lower and / or control the tension of the drill string; and / or to the mass of the drill, by changing the effective stiffness of the jar. In case the preload level is high, the pulling of the auxiliary rope starts from a lower stress state than if the preload level is less (which as a result makes the system as a whole less stretched).

However, the method of controlling the operational load described above is inconvenient.

Mainly, the reason for this is the need to twist the jar out of the drill in order to carry out the regulation.

This, in turn, entails the need to extract the drill, possibly from the very depth of the extended well, to a position on the surface of the well. This may take several hours.

After that, you need to remove the drill from the well, disconnect the auxiliary cable from the upper end of the jar and remove the jar from the drill. And only after that it is possible to get with a wrench to the installation nut, which is located in the free lower end part of the jar. Then, following the same steps, the time-consuming process of reassembling the drill and lowering it back into the well begins.

Considering the significant costs associated with the forced downtime of oil and gas well drilling rigs, there is a growing need for a more efficient method of regulating the operational load of a mechanical spring jar.

Moreover, in recent years, the strength of auxiliary ropes has mainly increased.

This means that the auxiliary ropes are able to operate with jars, the size of the springs of which and the magnitude of the operating loads are constantly increasing.

Despite this, the shoulder of the lock sub of the permanent packer and the lock keys limit the loads under which the spindle of the jar separates from the lock sub of the constant packer.

In particular, the known combination of a lock key and a groove of a lock sub of a permanent packer includes a lock key having a curved outer surface, which is a recess having one or more shoulders, the front side of which is directed upwards. The groove of the castle sub of the permanent packer has a protrusion of the form associated with the recess. Large loads during the operation of the auxiliary rope cause these pairs of bulges to slide relative to each other, thereby causing the spindle of the jar to separate from the lock sub of the permanent packer even before the lock keys engage with the cam surface.

In addition, the repeated use of high loads causes premature wear of the lock keys and groove.

Thus, there is a need to improve the design of the jar in order to more effectively secure its components to each other until they are deliberately disconnected.

SUMMARY OF THE INVENTION

According to a first aspect of the invention, a jar for use in an downhole drill includes a hollow casing;

jar spindle;

castle sub of the permanent packer;

at least one lock key;

cam surface;

a camera;

a compression spring and adjusting device, in which the hollow casing supports the spindle of the jar and the lock sub of the constant packer, which are kept in it in it;

the jar spindle and the lock sub of the permanent packer are interconnected in a detachable manner by means of at least one lock key, and each at least one lock key is movable between the locking position in which the lock sub of the constant packer and the jar spindle are interconnected, and an open position that allows them to disconnect from each other;

the cam surface may engage with at least one lock key,

- 3 008901 to move at least one lock key from the specified locking position to the specified open position when the spindle of the jar occupies a predetermined position inside the casing;

the compression spring is restrained inside the chamber and acts between the castle sub of the constant packer and the hollow casing so as to pressure deflect the spindle of the jar from a predetermined position after it is connected to the castle sub of the constant packer; and the adjusting device includes an adjusting spindle, which can rotate relative to the hollow casing, and has an outer part, which can be engaged from the outside of the hollow casing through its wall, and an adjusting part, which is screwed onto the jar spindle so that rotation the adjusting spindle with respect to the spindle of the jar changes the length of the chamber and, therefore, the degree of contraction of the compression spring.

This device allows you to successfully control the preliminary load on the compression spring of the jar without the need to dismantle the drill, of which the jar is a part. This reduces rig downtime.

Conveniently, the jar spindle includes an end portion protruding from the hollow casing; the connecting connector of the auxiliary cable is attached to this end part outside the hollow casing.

It is more preferable that the hollow casing includes an anvil rigidly attached to it, usually from the inside; and the jar’s spindle includes a hammer-shaped part that can hit this anvil as a result of the action of a taut auxiliary rope, causing the jar’s spindle to separate from the castle sub of the permanent packer.

The characteristic features mentioned above successfully enable the yasa according to the present invention to have the characteristics of traditional jars that are known to those who are experienced in this technical field.

It is preferable that the adjusting spindle at one end inside the hollow casing comprises a shank having a threaded end portion, and the compression spring has an outline of such a hollow cylindrical shape that this shank protrudes outward through its central channel; an adjusting device including a nut that is attached to the adjusting spindle and screwed onto said end portion of the shank.

Advantageously, this device is compact. This makes it possible to freely implement the adjustment device described above.

It is convenient that the compression spring includes in series, with mutual engagement between each other, a first spring segment having a first coefficient of elasticity, and a second spring segment having a second coefficient of elasticity.

It is convenient that the hollow casing contains an elongated through hole made therein, which allows you to monitor the position of the adjusting device relative to the casing.

It is also preferable that on the casing, next to the hole, one or more interval indicators are applied.

This makes it possible to adjust the adjusting device to set a predetermined degree of preload on the compression spring.

In a typical embodiment, three indexes of intervals are applied to the casing (although it is possible to apply another number of indicators), which in fact correspond to the known preload levels “low”, “medium” and “high”.

In a most preferred embodiment of the present invention, the outer part of the adjustment spindle includes a jar, as described above; this outer part of the adjusting spindle contains a hoop that can move relative to the rest of the adjusting spindle and has a protrusion that can engage with a shoulder placed in a hollow casing; this adjusting spindle contains a threaded portion having a lock nut screwed onto it, which, when twisted, engages with the hoop in order to force the protrusion to engage with the shoulder and thus prevent the action of the adjusting device.

It is also preferred that the locking sub of the permanent packer includes a hollow interior on the surface of which two or more clamping arms are made; and each lock key has at least two locking surfaces, each locking surface of the specified lock key can mesh with the specified shoulder of the adjacent packer lock sub when the lock key occupies its locking position with a jaw spindle inserted into the hollow interior of the lock sub permanent packer.

This device successfully solves the problem of auxiliary ropes of high strength, known in the previous technology, allowing the use of loads that cause premature separation of the spindle of the jar from the components of the castle sub of the permanent packer of traditional jars.

- 4 008901

In one embodiment of this invention, each said key lock includes one or more elastically deformable deflecting elements that cause it to move in the direction of its locking position.

The rights of the present invention also extend to a jar for use in a downhole drill containing a hollow casing;

jar spindle;

castle sub of the permanent packer;

at least one lock key;

cam surface;

a camera;

a compression spring and adjusting device, in which the hollow casing supports the spindle of the jar and the lock sub of the constant packer, which are kept in it in it;

the jar spindle and the lock sub of the permanent packer are interconnected in a detachable manner by means of at least one lock key, and each at least one lock key is movable between the locking position in which the lock sub of the constant packer and the jar spindle are interconnected, and an open position that allows them to disconnect from each other;

the cam surface may engage with at least one lock key to move it from its indicated locking position to its open position when the spindle of the jar occupies a predetermined position inside the casing;

the compression spring is restrained inside the chamber and acts between the castle sub of the constant packer and the hollow casing so as to pressure deflect the spindle of the jar from a predetermined position after it is connected to the castle sub of the constant packer;

the adjusting device includes an adjusting spindle, which can rotate relative to the hollow casing, and has an outer part, which can be engaged outside the hollow casing, in which the castle sub of the constant packer comprises a hollow inner part, on the surface of which two or more clamping arms are made; and each lock key has at least two locking surfaces, each locking surface of said lock key may mesh with said shoulder of the lock sub of the constant packer when the lock key takes its locking position with the spindle of the jar inserted into the hollow interior of the lock sub of the constant packer .

In other words, the rights of the present invention extend to a jar having a double surface of the lock keys discussed above, in the absence of the adjusting mechanism also described here.

The accompanying drawings, which are incorporated in and constitute a part of this detailed description, illustrate one embodiment of the invention and, together with this description, are useful for explaining the principles of this invention.

Brief Description of the Drawings

FIG. 1 is a longitudinal sectional view of a jar according to the invention;

FIG. 1a is a view of a circle highlighted in FIG. 1 on an enlarged scale;

FIG. 2 is a view of a portion highlighted in dash-dot line in FIG. 1 on an enlarged scale; and FIG. 2a is a view of a circle highlighted in FIG. 2 on an enlarged scale.

Information confirming the possibility of carrying out the invention

The following is a detailed description of an embodiment of the present invention, an example of which is shown in the accompanying drawings. In all the drawings, where possible, the same reference numbers are used with respect to the same or similar parts.

In the drawings, which represent a non-limiting example of a preferred embodiment of the invention, the jar 10 includes a hollow, cylindrical casing 11, typically typically made of stainless steel or any other material from an assortment that is commonly used in the manufacture of downhole tools.

The elongated, hollow casing 11 has an elongated, hollow, cylindrical inner part 12, inside which the spindle of the box 13 and the locking sub of the constant packer 14 are held in such a way that they can smoothly slide in the longitudinal direction inside the inner part 12.

The jar 10 is shown in configuration when it is in working condition in which the spindle of the jar 13 is located above the locking spindle 14.

The spindle of the jar 13 and the lock sub of the permanent packer 14 are cylindrical components with a diameter, usually slightly smaller than the diameter of the inner part 12, as a result of which they are a connection with a sliding fit in the inner part 12.

- 5 008901

The total length of the spindle of the jar 13 and the locking sub of the permanent packer 14 is less than the overall length of the hollow inner part 12, which allows the aforementioned sliding movement.

The spindle of the jar has around its cylindrical lower end part 13a a group of lock keys 16 attached to it and arranged around the circumference, which ensure fixing the spindle of the jar 13 and the lock sub of the permanent packer 14 with each other.

In the presented embodiment, there are two lock keys 16 located at an interval of 180 ° along the pitch circle outlined by a cylindrical lower end portion 13a. In other preferred embodiments of the invention, it is possible to use a different number of lock keys.

The hollow inner part 12 comprises a cam surface 17, which, in the embodiment of the invention shown in the drawings, is limited by a sleeve 18 fixed to the inner surface of the inner part 12 and an insertion surface 19, which extends radially inside the cone.

Thus, the cam surface 17 is a zone of the inner part 12, which with a uniform and gradual decrease in diameter leads to a plane-parallel section 19.

Within the scope of the present invention, it is undoubtedly possible to use other means to form the cam surface 17. For example, the sleeve 18 can replace or supplement a number of protrusions.

The hollow inner surface 12 adjacent to the upper end portion of the locking spindle 14 defines the boundaries of the face-down shoulder 22, defining one end of the hollow chamber 23.

The chamber 23 is an elongated cylindrical chamber containing a compression spring 24, the shape of which is essentially a hollow cylinder.

The upper end of the compression spring 24 provides resistance to the shoulder 22.

The lower end of the compression spring 24 resists the set nut 26, described in more detail below, which limits the lower end of the chamber 23.

The jar 10 contains an adjusting device, depicted, as a rule, under the reference number 27.

The spindle of the jar 13 includes a part in the form of a hammer 28, rigidly attached to it above the sleeve 18, through which the spindle of the jar protrudes.

The hammer-shaped part 28 is made in the form of a boss with grooves. Thus, the cylindrical boss is divided by four equally spaced angular intervals and elongated grooves 29, to determine the boundaries of the four quarter-cylinder pads 31.

The purpose of the grooves 29 is to allow fluid to flow past the hammer 28, thereby nullifying any piston effect that might otherwise occur in the hollow interior 12. As a result, the spindle of the jar 13 can smoothly slide in the longitudinal direction and rotate inside the inner part 12, along the sections indicated by reference numerals 32 and 33.

The hammer-shaped part 28 is attached to the spindle of the jar 13 by means of threaded parts engaged with each other. To prevent rotation of the part in the form of a hammer 28 relative to the spindle of the box 13, locking screws or other protective means can be used.

As can be clearly seen from FIG. 2 and 2a, each lock key 16 is held in a state of movable connection with respect to the cylindrical lower end portion of the spindle of the jar 13.

Each lock key 16 can radially move up and down with respect to the spindle of the jar 14. A corresponding compression spring 36 acts in the radial direction between the spindle of the jar 13 and each end of each lock key 16 so as to force the lock keys to deviate to the extreme from the center (locking) position with respect to the spindle of the jar 13.

Despite the fact that this is not visible from FIG. 2, compression springs 36 are rigidly attached at each end to a part of the lock key and a groove 37 formed in the cylindrical end part of the spindle of the jar 13, thereby preventing radial separation of the lock keys from the spindle of the jar 13.

Rejected compression springs 36 lock keys 16 occupy the locking position, allowing the transmitted load to fasten together the spindle box 13 and the lock sub of the permanent packer 14.

When the lock keys 16 are compressed inward in the radial direction under the action of the compression spring 36, they occupy an open position in which the spindle of the box 13 and the lock sub of the permanent packer 14 are separated from each other.

Each lock key 16 includes a pair of longitudinally spaced surfaces 20 that extend inwardly and are bounded by grooves, as shown in FIG. 2.

The jar 10 includes a hollow inner part of a cylindrical shape, which has a locking groove 38 formed on its inner surface in the upper end of the castle

- 6 008901 waterman of the permanent packer 14.

The locking groove 38 defines the boundaries of the pair located at a distance from each other in the radial direction and directed inwardly of the protrusions 41, placed during the working condition of the jar one above the other. As shown, these protrusions limit a pair of shoulders 39a, 39b, the front sides of which are directed downward.

When, as shown, the locking groove 38 is located above the locking keys 16, and the latter occupy their locking position, into which they are extruded by the springs 36, the arms 39a, b, limited by the protrusions 41 and the surfaces 20, engage to allow the transmission of forces, acting in the longitudinal direction between the castle sub of the permanent packer 14 and the spindle of the jar 13.

The presence in the locking groove 38 of two arms 39, which are meshed respectively with a pair of upward facing surfaces made in the lock keys 16, gives significantly greater reliability to the connection between the spindle of the jar 13 and the lock sub of the permanent packer 14 than has been possible so far.

The cam surface 17 may engage with the follower surface 42 made on the upper, outer end part of each of the lock keys 16. As a result, when the jar spindle moves upward with respect to the casing 11 (as a result of upward thrust applied to the jar spindle 13) , the driven surface 42 of each of the lock keys 16 is engaged with the tapered insertion portion 19 of the cam surface 17, thereby pushing the lock keys 16 radially inward with respect to the spindle of the jar 13, and forcing x otedinitsya from the locking groove 38 by the time when the locking keys 16 largely or completely within the portion having parallel sides 21 of the sleeve 18, cam surface 17 bounding.

The compression spring 24 is located within the chamber 23 and, as already noted, acts between the installation nut 26 and the shoulder 22, which is part of the hollow casing 11.

As described below, the mounting nut 26 is attached to the lock sub of the permanent packer 14 and is a part thereof, thus deflecting the spindle of the box 13 when it is connected to the lock sub of the constant packer 14 from the position where the driven surfaces 42 engage with cam surface 17.

The uppermost end of the spindle of the jar 13 is protruded through the hole 43, available in the uppermost end part of the casing 11.

The free upper end of the spindle of the jar 13 is terminated by a connecting connector 44 of the cable lock of the auxiliary cable or another type of connecting link of a standard design.

When the drill, in which the jar 10 according to the present invention is fixed, is stuck in the wellbore, the tension applied through the auxiliary cable attached to the connector 44 will pull up the spindle of the jar 13 and the locking sub of the permanent packer when the latter is connected to it.

This will happen with overcoming the elastic force of the compression spring 24, which during this movement will be compressed between the adjusting nut 26 and the shoulder 22 until the driven surfaces 42 of the corresponding lock keys 16 engage with the cam surface 17, thereby causing disconnecting the jar spindle from the lock sub of the permanent packer 14.

At this point, the potential energy in the auxiliary cable is converted into kinetic energy, which sharply pushes up the spindle of the jar 13. Since in the typical version the jar 10 contains several load rods mounted directly under the cable lock 24, they are also pushed up with a significant impulse of kinetic energy.

This makes the part in the form of a hammer 28 hit at the end of the anvil, made in the form of a sleeve 34 and located in line with the upper end part of the inner part of the casing 11 in working position, and thereby transmit an impulse to it. It is transmitted over shoulder 46 to the casing

11. The latter, in turn, applies an impulse to the drill under the jar in order to free the jammed equipment.

As already discussed above, it is desirable to adjust the effective compression ratio of the spring 24 in order to match the differing tensile strengths of the auxiliary rope used in combination with the jar 10, and the different masses of the drill.

For this reason, as already noted, it is important that the connection between the jade spindle and the lock sub of the permanent packer is disconnected until the voltage in the auxiliary cable causes the auxiliary cable to break.

To this end, the jar 10 according to the present invention includes an adjusting spindle 47, which is part of the adjusting device 27.

The adjusting spindle 47 can rotate relative to the casing 11.

The adjusting spindle 47 includes a cylindrical section 48 located inside the hollow casing 11 in the area located under the compression spring 24, and an external section 49, which can

- 7 008901 but to engage, for example, manually or using a tool from the outside of the hollow casing 11 through its wall.

This is the difference from the adjusting device of the previous technology, in which the installation nut is open for access only through the lowest part of the adjusting device of the jar 10.

The adjusting spindle includes an adjusting section 51, which is a hollow cylindrical part attached to the adjusting spindle 47 so as to be able to rotate with it.

The adjusting portion 51 ends with the adjusting nut 26.

The castle sub of the permanent packer 14 includes a shaft, or shank, 12, protruding in a downward direction from the cylindrical section 39.

The shaft 52 projects through a central channel bounded by a compression spring 24 and ends with a threaded portion 53 located in the lowest end portion of the operating state of the spring.

The mounting nut 26 is screwed onto the threaded portion 53.

The outer portion 49 of the adjusting spindle 47 includes an annular protrusion 54, which engages with an annular shoulder 56 in the lower end portion of the casing 11.

Thus, the rotation of the adjusting spindle 49, due to the engagement of its outer portion 49, causes the installation nut 26 to rotate in the adjustment section 51. This causes the setting nut 26 to be tightened or loosened on the threaded end portion 53 of the shank 52, thereby adjusting the length of the chamber 23 and applying to the compression spring 24 a preload of a greater or lesser magnitude, depending on the desire of the consumer.

Since the magnitude of the preload affects the ease with which the lock sub of the constant packer can be pulled up relative to the casing 11, the rotation of the adjusting spindle allows the various tensile strengths of the auxiliary rope and the weight of the drill to be freely matched.

Since the adjusting spindle 47 is open for access from the outside of the casing 11, without the need to remove the jar 10 from the drill, the adjustment process is facilitated and becomes much faster than when using techniques of the previous technology.

In the apparatus of the present invention, the annular end portion of the sleeve 34 serves as an anvil component. However, it is possible within the scope of the present invention to use other forms of the hammer-shaped part 38 and the anvil-shaped part 34, in addition to those presented in this example.

As clearly follows from FIG. 1 and 2, in a preferred embodiment, the compression spring 24 is a combination spring comprising two spring sections 57 and 58 with different elastic coefficients.

Each of the spring sections 57, 58 presented in the present preferred embodiment consists of a series of spring disks arranged in one unit. However, within the scope of the present invention, the use of a large number of other equivalent devices is possible.

The casing 11 includes an elongated through hole 59 made therein, through which you can see the placement of the installation nut 26 relative to the shank 52, and, therefore, set the amount of preload applied to the compression spring 24.

On the wall of the casing 11, located next to the window 59, a number of marks or other signs 61 are applied, which provide an indicative indication of the applied preload.

In practice, three marks 61 are applied, which are applied at approximately the same distance from each other to show the positions of the adjusting nut 26 corresponding to low, medium and high levels of preload, respectively.

At the very bottom of the adjusting spindle 47, under the outer section 49, there is a cylindrical threaded section 62 protruding downward onto which the connector standard 63 for drill bits is screwed.

It is possible to use other types of connector within the scope of the present invention than the one presented in this example. For example, you can use the connector of the locking mechanism of the auxiliary rope, such as presented in US patent application No. 09/730544.

On the part of the cylindrical section 62, located between the connecting connector 63 of the drill string and the outer section 49 of the adjusting spindle 47, there is a lock nut 64, which is screwed onto the cylindrical section 62. When tightening on the part 49, the lock nut 64 forces the protrusion 54 to enter friction engagement with the shoulder 56, thereby preventing rotation of the set nut 26 with respect to the shank 52. This, in turn, fixes a predetermined amount of preload acting on the compression spring 24.

The jar according to the present invention can be used with auxiliary ropes for extra heavy loads with greater speed and reliability than was possible in the previous technology.

Claims (12)

1. A jar for use in an downhole drill, including a hollow casing; jar spindle; castle sub of the permanent packer; at least one lock key; cam surface; a camera; a compression spring and adjusting device, in which the hollow casing supports the spindle of the jar and the lock sub of the constant packer, which are kept in it in it; the jar spindle and the lock sub of the constant packer are interconnected in a detachable manner by means of at least one lock key, and each said lock key is in a movable state between the locking position, in which the lock sub of the constant packer and the jar spindle are connected to each other, and the open position, allowing them to disconnect from each other; the cam surface may engage with each specified lock key to move each specified lock key from the specified locking position to the specified open position when the spindle of the jar occupies a predetermined position within the casing; the compression spring is restrained inside the chamber and acts between the castle sub of the constant packer and the hollow casing so as to pressure deflect the spindle of the jar from a predetermined position after it is connected to the castle sub of the constant packer; and the adjusting device includes an adjusting spindle, which can rotate relative to the hollow casing, and has an outer part, which can be engaged outside the hollow casing through its wall, and an adjusting part, which is screwed onto the jar spindle so that rotation the adjusting spindle with respect to the spindle of the jar changes the length of the chamber and, therefore, the compression ratio of the compression spring. 2. The jar according to claim 1, in which the spindle of the jar includes an end portion protruding from the hollow casing, and a connecting connector of the auxiliary cable is attached to the specified end part outside the hollow casing. 3. The jar according to claim 1, in which the hollow casing includes a hard anvil attached to it, and the spindle of the jar includes a hammer that can hit this anvil as a result of the action of the tensioned auxiliary rope, causing the jar to separate from the constant lock sub packer. 4. The jar according to claim 1, in which the spindle of the jar includes, at one end, inside the hollow casing, a shank having a threaded end portion, in which the compression spring has such a hollow cylindrical shape that this shank passes through its central channel, and wherein the adjustment device includes a nut that is attached to the adjustment spindle and screwed onto said end portion of the shank. 5. The jar according to claim 1, in which the compression spring includes in series, with mutual engagement between each other, a first spring segment having a first coefficient of elasticity, and a second spring segment having a second coefficient of elasticity. 6. The jar according to claim 1, in which the hollow casing comprises an elongated through hole made therein, allowing monitoring the position of the adjusting device with respect to the casing. 7. The jar according to claim 1, in which the hollow casing comprises an elongated through hole made therein, allowing monitoring the position of the adjusting device with respect to the casing, and one or more interval indicators are applied to the casing next to the opening. 8. The jar according to claim 1, in which the outer part of the adjusting spindle contains a hoop that can move relative to the rest of the adjusting spindle and has a protrusion that can engage with a shoulder placed in the hollow casing, and in which the adjusting spindle contains a threaded portion having a lock nut screwed onto it, which, when twisted, engages with the hoop in order to force the protrusion to engage with the shoulder and thus prevent the adjustment device I. 9. The jar according to claim 1, wherein the locking sub of the permanent packer includes a hollow interior on the surface of which two or more clamping arms are made, and each said locking key has at least two locking surfaces, each said locking surface of said locking the key can engage with the specified shoulder of the adjacent lock packer of the permanent packer located nearby when the lock key takes its locking - 9 008901 laying with the spindle of a jar, let into the hollow interior of the castle sub of the permanent packer. 10. The jar according to claim 1, in which each specified key lock includes one or more elastically deformable deflecting elements that cause each specified key lock to move in the direction of its locking position. 11. A jar for use in an downhole drill, including a hollow casing; jar spindle; castle sub of the permanent packer; at least one lock key; cam surface; a camera; a compression spring and adjusting device, in which the hollow casing supports the spindle of the jar and the lock sub of the constant packer, which are kept in it in it; the jar’s spindle and the lock sub of the permanent packer are interconnected in a detachable manner by means of at least one lock key, each specified lock key is in a movable state between the locking position, in which the lock sub of the constant packer and the jar spindle are connected to each other, and an open position, allowing they disconnect from each other; the cam surface may engage with at least one lock key to move each specified lock key from its locking position to the open position when the jar spindle has a predetermined position inside the casing; the compression spring is restrained inside the chamber and acts between the castle sub of the constant packer and the hollow casing so as to pressure deflect the spindle of the jar from a predetermined position after it is connected to the castle sub of the constant packer; the adjusting device includes an adjusting spindle, which can rotate relative to the hollow casing, and has an outer part, which can be engaged outside the hollow casing, in which the castle sub of the constant packer comprises a hollow inner part, on the surface of which two or more clamping arms are made, and each said locking key has at least two locking surfaces, each locking surface of said locking key may mesh with said shoulder the lock sub of the permanent packer, when the lock key occupies its locking position with the spindle of the jar that is let into the hollow interior of the lock sub of the constant packer. 12. The jar according to claim 11, in which each of the specified key lock includes one or more elastically deformable deflecting elements that cause it to move towards its locking position.